EFFECT OF VARIOUS CARBON AND NITROGEN SOURCES ON THE GROWTH AND SPORULATION OF
MICRO XYPHIELLA
HIBISCIFOLIA
BY K . S. THIND,F.A.Sc. AND M m A ]VfADAN (Department of Botany, Panjab University, Chandigarh-14) Received June 29, 1973 ABSTRACT
The carbon and nitrogen nutrition of Microxyphiella hibiscifolia Bat., Nasc., and Cif., isolated from the leaves of cotton (Gossypium hirsutum L.), was studied at 28° C for 14 days at pH 4.0. Out of forty-one carbon compounds tested, the pathogen showed excellent growth on dextrose, sucrose, starch, raffinose and maltose; good on inulin; fair on melibiose and galactose ; and poor or no growth on rest of the carbon compounds. The pathogen showed excellent sporulation on all the carbohydrates, in general. Out of thirty-thrGe nitrogen compounds tested, the pathogen showed excellent growth on peptone, asparagine, proline, ammonium oxalate, yeast extract, ammonium phosphate, ammonium sulphate; good on ammonium chloride, serine, ammonium nitrate, urea, sodium nitrate, potassium nitrate, histidine mono HC1 and histidine di HCI; fair on glutamic acid, lysine mono HC1, arginine mono HCI, threonine, nor-valine and glycine; and poor or no growth on rest of the nitrogen compounds. The pathogen showed excellent or good sporulation, in general, on all the nitrogen compounds. The utilisation of potassium nitrite was conditioned by the pH of the medium.
INTRODUCTION
M. hibiscifolia was isolated from the cotton leaves obtained from Hissar (Haryana) in the months of October and November, 1969. Several monosporic isolates of the fungus were made separately on potato dextrose agar slant(peeled and sliced potatoes 200 g, dextrose 20 g, agar 20 g, and distilled water 1,000 ml). No.marked morphological variation among its various isolater was observed and, therefore, one representative isolate was selected to study the effect of carbon and nitrogen compounds on the growth and sporuiation of M. hibiscifolia. No such studies have been carried out previously on this organism. 143 Acad. B I
144
K.S.
THIND
AND M I R A M A D A N
MATERIAL AND METHODS
The study on carbon and nitrogen nutrition of M. hibivcf~lia was carried out with liquid basal medium of the following composition : dextrose 20 g, asparagine 3.740 g, KH2PO~ 10 g, ~vlgSO~,7H~O 0.250 g, Fe~ (SO4)3. 6H~,,O 0.005 g, and distilled water 1,003 ml. This basal medium was found to give excellent growth of this fungus in the preliminary experiments. In order to study the effect of various carbon* artd nitrogen** sources, they were substituted singly by dextrose and asparagine, respectively, in the basal medium. The amount of these substances was so adjusted as to furnish the same quantity of carbon artd nitrogen, which was present in the basal medium. Twenty-five millilitres of medium were poured in 100 ml Pyrex glass Erlenmayer flasks and three replicates were taken in each case. The various media were sterilized at 7 lb./sq, inch steam pressure for half-an-hour. Initial pH of the various media was. adjusted to 4.0 after autoclaving. However, a solution of various carbon compounds was prepared separately in distilled water, adjusted to pH 7.0 and then sterilized in the autoclave to minimise the possibility of their breakdown during autoclaving. The solution of remaining ingredients of the basal medium was sterilized in the autoclave without adjusting to the optimum pH. A carbon solution and the solution of remaining ingredients of the basal medium were then mixed together proportionally to get a normal strength of the basal medium and pH was adjusted to 4.0. The spore suspension was prepared in sterilized distilled water from 6 days old culture. The medium in each flask was inoculated with 1 ml standardised spore suspension (8-16 spores per low power field of the compound microscope). It may be mentioned here that pH 4.0, temperature 28 ° C and incubation period of 14 days were found to be optim u m conditions for the growth of M. hibiscifolia by preliminary experiments. The cultmes were filtered and dried at 60 ° C to a constant weight in hot air overt for 24 hours. The data were recorded in terms of final pH, sporulation and dry weight of the mycelium. For the estimation of spore concentration in different experiments, each culture flask was shaken and the fungal growth was mixed thoroughly by * Soluble starch, pectin and inulin were added at the rate of 20 g each while oils were added at the rate of 20 ml each per litre of the basal medium. ** Peptone, yeast extract and casein hycholysate were added at the rate of 5 g each per litre of the basal medium.
Growth and Sporulation of Microxyphiella hibiscifolia
145
means of glass rod in order to get a homogenous mixture. After shaking thoroughly, drops were taken from this homogenate and the spore count was estimated under low power of the compound microscope. The degree of sporulation was measured on the basis of average number o f spores present per low power field of the compound microscope and recorded in the following grades : No. of spores per low power field of the microscope
Degree of sporulation
Symbol used
No spore
Nil
1 - 10
Poor
q-
10 - 20
Fair
+ +
20 - 30
Good
-t- q- +
Above 30
Excellent
+ q- ÷ q-
The growth of the fungus on different media has been termed excellent, good, fair and poor on the basis of its following mycelial weights :
Category
Dry weight, mg
Excellent
Above 150
Good
100-150
Fair
50-100
Poor
Below 50 EXPERIMENTAL WORK
Car~n nutrition.--A total of sixteen carbohydrates comprising three pentoses, five hexoses, four disaccharides, one trisaccharide and three polysaccharides were used singly as the sole source of carbo~l in order to observe t h e i r effect on the growth and sporulation o f M. hibiscifolia. The data on dry weight, sporulation and final pH are summarised in Table 1. M. hibi-
146
K . S . THIND AND MIRA MADAN
scifolia showed excellent growth on dextrose, sucrose, starch, raffinose and
maltose; good on inulin; fair on melibiose and galactose; poor on lactose, pectin, fructose, arabinose, sorbose and mannose; and no growth on xylose and ribose. There was no sporulation on xylose, ribose and mannose; p o o r TABLE I
Effect of different carbohydrates used singly as the sole source of carbon on the growth and sporulation of M. hibiscifolia after 14 days of incubation at 28 ° C. Initial p H adjusted to 4.0 Carbon source Control (witho'A carbon)
Dry wt. in mg
Sporulation Final pH
0
--
4-0
0
--
4-0
18
q-
4-5
0
--
4.5
186
Jr -k -k -k
4.8
25
-k + - k _L
4" 5
Mannose
8
--
4.8
D (+)-Galactose
85
+ + + +
5.6
L-Sorbose
12
-I-
4.3
Sucrose
180
+ -t- + +
4.0
Lactose
30
-t- + q- +
4.2
150
-k -k -k q-
4.1
87
-t--k-{-+
5-2
Raffinose
160
q- + -t- -}-
5.6
Inulin
125
+ q- -}-+
4.8
Starch
180
+ -k + -t-
5.3
Pectin
30
-k -~ -q--t-
3.6
Carbohyarates D (-k)
Xylose
L (+)
Arabinose
D (--)-Ribose Dextrose D (--)-Fructose D (--)
D-Maltose D (+)
Melibiose
Growth and Sporulation of Microxyphiella hibiscifolia
147
on arabinose and sorbose while it was excellent on all other carbohydrates. The pH increased slightly to considerably in all the carbohydrates except pectin in which case the pH fell down slightly. However, there was no change in pH in the case of sucrose. Sorbose is utilized poorly or not at all by the fungi, in general. It has been reported not only unutilisable for many fungi but also toxic for several others. The toxicity is evidenced by the death of hyphal tips followed by meagre branching of mycelium below the killed portions (Lilly and Barnett, 1953). It has been suggested that this sugar interferes with the respiratory pathway of these microorganisms. In order to find out whether the poor growth of M. hibiscifolia on sorbose is due to inhibitory effect or its nonutilisation, an experiment was set up as follows: Equivalent amount of good carbon sources so as to furnish 8 g/1 of carbon, which is present in 20 g/1 of dextrose, was added to the basal medium containing sorbose. The mixture of two carbohydrates, therefore, furnished twice the amount, i.e., equivalent to 40 g dextrose pel litre. A control with 40 g/1 dextrose was set up to study if there was arty adverse effect on the growth of fungus due to the increased amount of total sugars. Twenty-five milli. litres of medium were poured in each flask and three replicates were taken in each case. Rest of the procedure was as usual. The data on dry weight, spolulation and final pH are given in Table II. It is clear from the table that sorbose markedly inhibited the growth of M. hibiscifolia in the presence of dextrose and sucrose and to some extent in the presence of maltose, raffinose, inulin and starch. Therefore, it appears to be inhibitory to the growth of this pathogen. Six alcohols, five oils and fourteen organic acids were used as the sole source of carbon for the growth and sporulation of M. hibiscifolia. The data on dry weight, sporulation and final pH are summarised in Table III. It is apparent from the data that M. hibiscifolia showed poor growth on mannitol ethyl alcohol and succinic acid and no growth on rest of the carbon compounds. The pathogen showed good sporulation on mannitol and succinic acid; fair on ethyl alcohol; and no sporulation on rest of the carbon compounds.
Nitrogen nutrition.--Some inorganic and organic nitrogenous compounds were tested as the sole source of nitrogen for the growth and sporulation of this pathogen in one experiment. The data on dry weight, sporulation and final pH are summarised in Table IV. It is apparent from the data that
148
K . S . TaINo ANt) Mw.~ MADAN TABLE II
Effect of sorbose used singly and in combination with other carbon sources on the growth and sporulation of M. hibiscifolia after 14 days of incubation at 28 ° C. Initial p H adjusted to 4.0
Carbon source
Dry wt. in mg
Sporulation
Final pH
22C
+-t- + +
5.0
-k
4.3
190
-b + + -1-
4.8
30
-? + + +
4.9
182
+ -k + +
4.0
36
+ +-k-I-
4- 5
153
+ +-k +
4.1
++++
4.5
+ + + +
5-6
++++
5.1
128
+ + + +
4.8
78
+ + + +
4.5
Starch
176
+ + + +
5.3
Starch + sorbose
I00
++÷+
5.0
Dextrose 46 g/l Sorb ose Dextrose Dextrose + sorbose Sucrose Sucrose + sorbose Maltose Maltose + sorbose Raffinose Raffinose + sorbose Inulin Inulin + sorbose
15
89 158 89
M. hibiscifolia showed excellent growth on peptone, asparagine, a m m o n i u m oxalate, yeast extract, ammonium phosphate and ammonium sulphate; g o o d on ammonium chloride, ammonium nitrate, urea, sodium nitrate and potassium nitrate; and poor on casein hydrolysate. However, there was neither any growth nor spo~ulation on potassium nitrite. The fungus showed excellent sporulation on all the inorganic artd organic sources except casein h y d r o lysate which showed poor sporulation. There was a slight or no p H change
Growth and Sporulation o f M i c r o x y p h i e l l a h i b i s c i f o l i a
149
TABLE III
Effect of different alcohols, oils and organic acids used singly as the sole source of carbon on the growth and sporulation of M. hibiscifolia after 14 days of incubation at 28°C. lnitial p H adjusted to 4 - 0 C a r b o n source C o n t r o l (without c a r b o n )
Dry wt. in mg. 0
Sporulation --
Final pH 4-0
Alcohols : Marmitol
20
÷ ÷ q-
6.2
Dulcitol
0
--
4.0
Methyl alcohol
0
--
4.0
16
+ q-
6.0
Isopropyl alcohol
0
--
4 -0
n-Butyl alcohol
0
--
4.0
Ethyl alcohol
Oils : Castor oil
0
--
4.0
Olive oil
0
--
4.0
C o t t o n seed oil
0
--
4-0
A l m o n d oil
0
--
4-0
C o c o n u t oil
0
--
4- 0
F o r m i c acid
0
--
4.0
Acetic acid
0
--
4.0
P r o p i o n i c acid
0
--
4.0
Organic acids :
Butyric acid
0
--
4.0
n-Velaric acid
0
--
4.0
Stearic acid
0
---
4.0
Lactic acid
0
--
4.0
Oxalic acid
0
--
4- 0
Maleic acid
0
~
4.0
12
+ ÷ q-
4.6
Sebacic acid
0
--
4.0
Malic acid
0
--
4.0
Succinic acid
Tartaric acid
0
--
4.0
Citric acid
0
--
4.0
150
K . S . TI-nND AND MIRA MADAN
in the case of nitrates, nitrites, ammonium oxalate, ammonium nitrate and asparagine. However, pH fell down considerably in the case of other ammonium salts and rose appreciably in the case of uroa, peptone, yeast extract and casein hydiolysate. In all cases pH remained in the acidic range. TABLE IV
Effect of different inorganic and organic nitrogenous compounds used singly as the sole source of nitrogen on the growth and sporulation of M. hibiscifolia after I4 days of incubation at 28° C. Initial pH adjusted to 4.0 Nitrogen source Control (without nitrogen)
Dry wt. in mg. Sporulation 0
Potassium nitrate
130
Potassium nitrite
0
Final pH
--
4.0
++++
4.0
--
4.0
Sodium nitrate
136
++++
4.0
Ammonium oxalate
1~/9
++++
4.6
Ammonium sulphate
152
++++
2.5
Ammonium nitrate
137
+++ +
4.8
Ammonium chloride
148
++++
2-6
Ammonium phosphate
160
+ +++
2.6
Urea
137
++++
5.9
Asparagine
188
+ ++ +
4.7
Peptone
200
++ ++
6- 0
Yeast extract
165
q- + + +
5.8
18
+
5.6
Casein hydrolysate
H-ion concentration is known to influence markedly the utilisation of KNO~ by different fungi. Therefore, an experiment was set up to find out the effect of whole range of pH on the growth and sporulation of M. hibiscifolia on KNO~. It is clear from Table V that this pathogen did not make any growth on acid pH range of 3.0-6.0, whil0 made some growth at pH
Growth and Sporulation o f Microxyphiella hibiseifolia 7.0-10'0 but no growth at pH 10.0. sporulation at pH 7.0-10.0.
151
However, the fungus showed good
TABLE V
Effect of different hydrogen-ion concentration on the utilization of potassium nitrite for the growth and sporulation of M. hibiscifolia after 14 days of incubation at 28 ° C Initial pH
Dry wt. in mg Sporulation
Final pH
2-0
0
--
2.0
3 -0
0
--
3.0
4-0
0
~
4.0
5"0
0
~
5"0
6-0
0
~
6.0
7-0
18
+++
6.5
8-0
38
+++
7.1
9-0
25
+++
7-6
10.0
12
+++
7.9
11.0
0
--
8.2
Twenty amino acids were tested as the sole source of nitrogen on the growth and sporulation of M. hibiscifolia. The data on dry weight, spolulation, and final p H are summarised in Table VI. M. hibiscifolia showed excellent growth on proline; good on serine, histidine mono HC1, histidine di HC1 ; fair on glutamic acid, lysine m o n o HC1, mginine mono HC1, threenine, nor-valine and glycine; poor on aspartic acid, phenylalahne, tryptophane, methionine, iso-leucine, tyros'me, leucin::, valiae and alar~in6; and no growth on cystine. The fungus showed poor sporulation on alanine and methionine and exceUent or good sporulation on rest of the amino acids. The pH fell down slightly to considerably in all amino acids except arginine mono HC1 and prohne in which case it iucreased slightly to appreciably, respectively.
152
K . S . THIND AND MIRA MADAN
However, there was no chartge in pH in the case of control and cystine on which there was no growth. TABLE VI
Effect of different amino acids used singly as the sole source of nitrogen on the growth and sporulation of M. hibiscifolia after 14 days of incubation at 28 ° C. Initial p H adjusted to 4.0
Nitrogen source
Control (without carbon) Glycine DL-iso-Leucine L-Leucine /~-Alanine DL-valine DL-nor-Valine DL-Threonine DL-Serine L-Proline L-Cystine DL-Methionine L-Arginine mono HC1 L-Lysine mono HC1 DL-Aspa~fic acid L-Glutamic acid L-Phenylalanine L-Tyrosine DL-Tryptophane L-Histidine mono HCl DL-Histidine di HC1
Dry wt. in mg
0 52 20 15 12 15 59 61 139 186 0 23 67 81 38 93 28 20 24 123 118
Sporulation
Final pH
--
4-0
+ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + -q+ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +
3- 7 3.2 2.4 3- 8 3.3 3- 3 3-4 3.7 5.8 4-0 3.5 4- 7 3.4 3 -4 4.2 3- 3 3.3 3.6 3-8 3.7
In order to find out whether cystirte is a poor source of nitrogea or it is inhibitory to the growth and sporulation of this pathogon, the following experiment was set up :
Growth and Sporulation of Microxyphiella hibiseifolia
153
Equivalent amount of an amino acid so as to furnish 693 rag/1 of nitrogen, which is present in 3.740 g/l of asparagine, was added to the basal medium containing cystine. The mixture of two amino acids, therefore, furnished twice the amount of nitrogen, i.e., equivalent to 7.480 g/l of asparagine. Twenty-five millilitres of the basal medium were poured in each flask and three replicates were taken in each case. Rest of the procedure was as usual. The data on dry weight, sporulation and final pH are summarised in Table VII. It is apparent fiom the data that cystine inhibited the growth of M. hibiscifolia to some extent in the presence of other amino acids which were good supporters of its growth. Thus it is an inhibitory somce of nitiogen foi the growth of this pathogen. TABLE VII
Effect of cystine used singly and in combination with other amino acids on the growth and sporulatwn of M. hibiscifolia after 14 days of incubation at 28 ° C. Initial pH adjusted to 4.0
Nitrogen source
Cystine Serine Serine + cystine Proline Proline + cystine Histidine mono HCI Histidine mono HC1 + cystine
Dry wt. in mg
0
Sportdation
Final pH
--
4.0
144
++ + +
3.7
60
+ + ++
4.0
188
+ + ++
5.8
90
+ + ++
5.2
125
+ + ++
3" 8
80
++ + +
3.9
DISCUSSION Different carbon compounds affected the growth of M. hibiscifolia differently. Pentoses usually do not support good growth of fungi and, similarly, xylose, arabinose and ribose supported poor or no g~owth of M. hibiscifolia studied here,
154
K. S. THIND AND MIRA MADAN
Dextrose, sucrose, starch, raffinose and maltose supported excellent growth of M. hibiseifolia. Similarly, a very large number of fungi have been reported by various workers to make excellent or good growth on these carbon sources. Generally, inulin serves as a poor source of carbon for the growth of fungi, which is due to their failme to secrete the appropriate enzyme inulase rather than its inhibitory effect (Hawker, 1950). However, it supported good growth of M. hibiscifolia. Similalry, Prasad (1967) recorded good growth of Pestalotia pauciseta on inulin.
M. hibiscifolia made fair growth on melibiose and galactose. Similarly, fair growth on melibiose has been reported for Linderina penni~pora and L. macrospora (Chan and Stephen, 1968). M. hibiscifolia studied here made poor growth on lactose, pectin, fructose, sorbose and mannose. Out of these fructose, mannose and pectin are good while lactose and sorbose are poor sources of carbon for the growth of fungi, in general. It is clear from Table II that sorbose markedly inhibited the growth of M. hibiscifolia in the presence of dextroes and sucrose and to some extent in the presence of maltose, raffinose, inulin and starch and thus it is inhibitory for the growth of this pathogen. Similarly, Murray and Andrian (1960) reported that sorbose severely inhibited the growth of Neurospora crassa (wild type) when mixed with galactose and fructose. Lilly and Barnett (1953) reported that the inhibitory effect of sorbose was more pronounced in the presence of maltose than glucose or sucrose. Thind and Madan (1967) reported that sorbose showed maximum growth inhibition of Cephalothecium roseum with fructose and minimum inhibition with dextrose, starch and maltose. Bilgrami (1963), on the other hand, showed that utilisation of sorbose by Phyllosticta spp. was considerably increased when used in combination with good carbon source like sucrose, maltose or glucose, etc. In general, alcohols, oils and organic acids are poo~ sources of carbon for the growth of fungi. Similany, M. hibiscifolia showed poor growth on mamfitol, ethyl alcohol and succinic acid and no growth or~ rest of these carbon compounds.
M. hibiscifolia showed poor sporulation with arabinose and no sporulafion with xylose and ribose. Similarly, pentoses, generally, ate poor sources of carbon for the growth as well as for the sporulafion of fungi.
Growth and Sporulation of Microxyphiella hibiscifolia
i55
Dextrose, fructose, galactose, sucrose, lactose, maltose, melibiose, raffinose, inulin, starch and pectin supported excellent sporulation of M. hibiscifolia. All these carbohydrates except lactose and inulin have been reported to show excellent or good sporulation for fungi, in general. Mannose which proved to be a poor source for the growth did rtot yield any sporulation of this pathogen. However, this sugar has been reported to be excellent or good source of carbon for the sporulation of many fungi, such as Colletotrichum hzamdarii and Alternaria citri and A. tenu& (Hasija, 1965; 1970), C. roseurn (Thind and Madart, 1967) and Botryodiplodia ananassae and Macrophomina phaseoli (Bhargava, 1971). Sorbose is known to be a poor source of carbon for the growth as well as sporulation of a large number of fungi. Similarly, it induced poor growth and sporulation of the present fungus. M. hibiscifolia showed good sporulation on maanitol and succinic acid; fair sporulation on ~thyl alcohol; and no sporulation on rest of the alcohols, oils and organic acids. All these carbon compounds, in general, are poor sources for the growth as well as sporulation of fungi.
The pathogen studied here made excellent or good growth on nitrates of potassium and sodium and various ammonium salts. A majority of the fungi are known to utilise nitrate and ammonium nitrogen well. A great majority of the fungi are unable to utilise nitrite as the nitrogen source at their optimum pH values, which are generally below 7.0. Nitrites have been reported to be toxic on the acidic pH range (Cochrane, 1950, 1958; Cochrane and Conn, 1950; Lilly and Barnett, 1951). Likewise, M. hibiscifolia could not make any growth on acidic pH range of 2.0-6-0 while it made poor growth on pH 7.0-10"0 and no growth at pH 11.0. Similar results have also been reported for Cercospora sl0p. (Thind and Mandahar, 1965) Pleospora indica (Mandahar, 1965) and C. roseurn (Thind and Madasl, 1969). Urea supported good growth of M. hibiscifolia as is true of Cercospora hibiscina (Thind and Maxtdahar, 1965) and C. roseum (Thirtd a~d Madan, 1967). Asparagine, in general, has been reported to be a good source of nitrogen for the growth of fungi investigated by various workers. Similarly, it yielded excellent growth of this pathogen. Peptone and yeast extract supported excellent growth while casein hydrolysate supported poor growth of M. hibiscijolia. All these nitrogen sources have been reported to support excellent or good growth of a large number of fungi. However, some fungi axe known to make poor or no growth on casein hydrolysato, such as Colleto-
156
K . S . TrIIND AND MIRA MADAN
trichum capsici (Thind and Randhawa, 1957) and Phallus revenelii and Crucibulum levis (Howard and Howard, 1969). M. hibiscifolia made excellent or good growth on proline, serine, histidine mono HC1 and histidine di HC1. Out of these proline and serine are generally good sources of nitrogen for a great majority of fungi studied by various workers so far. Histidine mono HC1 and histidine di HC1 are well utilised by some fungi but poorly by others. Glutamic acid, lysine, arginine, threonine, nor-valine and glycine made fair growth of M. hibiscifolia. Similarly, lysine supported fair growth of C. capsici (Thind and Randhawa, 1957) and P. indica (Mandahar, 1965) ; nor-valine of C. hibiscina (Thind and Mandahar, 1965); and glycine of some members of Saprolegniaceae (Bhargava, 1945). However, glutamic acid, arginine and threonine have been reported to show excellent or good growth of many fungi, such as C. hibiscina (Thind and Mandahar, 1965), P. indica (Mandahar, 1965) and C. roseum (Thind and Madam 1969). Aspartic acid, phenylalanine, tryptophane, methionine, iso.leucine , tyrosine, leucine, valine, alanine supported poor growth while cystine supported no growth of the present fungus. Out of these cystine and methionine are generally poor sources of nitrogen (Pelletier and Keitt, 1954). Likewise, tryptophane has been reported to support pool growth of P. indica (Mandahar, 1965), P. ravenelii and C. levis (Howard and Howard, 1969) and Helminthosporium spp. (Reddy, 1971); aspartic acid poor growth of Zygorhynchus spp. (Sarbhoy, 1965) and Tieghemiomyces parasiticus (Barnett, 1970); phenylalanine poor growth of Zygorhynehus moelleri and Z. exponens (Sarbhoy, 1965); tyrosine poor growth of C. capsici (Thind and Randhawa, 1957); leucine poor growth of Z. exponens (Sarbhoy, 1965); valine poor growth of Helminthosporium rostratum (Agarwal and Shinkhede, 1959); and alanine poor growth of Tilletia caries (Zscheile, 1951) and Helmin. thosporium nodulosum (Reddy, 1971). Cystine inhibited the growth of M. hibiscifolia to some extent in the presence of serine, proline and histidine mono HC1. Similarly, Lewis (1957) reported cystine a contsant inhibitor for the growth of Alternaria solani in the presence of other amino acids.
Potassium and sodium nitrates and all ammonium salts tested yielded excellent sporulation of M. hibisc~olia. These are known to be excellent or good sources of nitrogen for the growth as well as sporulation of fungi, in general. Urea, asparagine, peptone, yeast extract and casein hydrolysate, in general, are excellent or good sources of nitrogen for the growth as well as sporu-
Growth and Sporulation of Microxyphiella hibiscifolia
157
lation of fungi. All these nitrogort sources except casein hydrolysate supported excellent or good growth as well as sporulation of M'. hibiscifolia. However, casein hydrolysate, which was a poor supporter of growth, yielded poor sporulation of this pathogen. Amino acids, in general, are known to be good sources of nitrogen for the growth as well as sporulatioll of fungi. Howevet, M. hibiscifolia, which showed varying growth on all the amino acids tested, yielded excellent sporulation on all of them except alanine and methionine. REFERENCES Agarwal, G. P. and Shinkhede, C. G.
"Physiological studies on Helminthosporium Drechs," Phyton., 1959, 13, 45-54.
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" The utilization of L-sorbose by some pathogenic species of Phyllosticta," Proc. Indian Acad. Sci., 1963, 57 B, 230-34.
Chan, C. and Stephen, R. C.
" Utilisation of different carbon sources by genus Linderina,', Canad. Jour. Bot., 1968, 46, 751-56.
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" The metabolism of species of Streptomyces. Ili. The nitrate metabolism of S. griseus," Bull Torrey Bot. Club, 1950, 77, 176-80.
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----~
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